What is the difference between O(n^2)
and O(n.log(n))
?

n^2 grows in complexity more quickly. 


You'll need to be a bit more specific about what you are asking, but in this case 


http://www.cs.georgetown.edu/~alspaugh/cls/2009b072/algorithmAnalysis.html n log(n) grows significantly slower 


Big O calculates an upper limit of running time relative to the size of a data set ( An EDIT: Thanks to 'harms', I'll correct a wrong statement in my first answer: I told that when considering the worst case Sample: Say we have the worst case and our data set has size 100.
The problem is that both can be multiplied by a constant factor, say we multiply
So for I have to update my statement: For every problem, when considering the worst case, a The reason is: The choice of 


Algorithms that run in O(nlog(n)) time are generally faster than those that run in O(n^2). BigO defines the upperbound on performance. As the size of the data set grows (n) the length of time it takes to perform the task. You might be interested in the iTunes U algorithms course from MIT. 


"Big Oh" notation gives an estimated upper bound on the growth in the running time of an algorithm. If an algorithm is supposed to be O(n^2), in a naive way, it says that for n=1, it takes a max. time 1 units, for n=2 it takes max. time 4 units and so on. Similarly for O(n log(n)), it says the grown will be such that it obeys the upper bound of O(n log(n)). (If I am more than naive here, please correct me in a comment). I hope that helps. 

